Allorestricted peptide-specific t cells

ABSTRACT

The present invention is directed to a T cell receptor (TCR) recognizing antigenic peptides derived from tumor-associated antigen FMNL1/KW13 and being capable of inducing peptide specific killing of a target cell. The present invention is further directed to one antigenic peptides derived from tumor-associated antigen FMNL1/KW13, to an antigen specific T cell, comprising said TCR, to a nucleic acid coding for said TCR and to the use of the antigen specific T cells for the manufacture of a medicament for the treatment of malignancies characterized by overexpression of FMNL1/KW13.

The present invention is directed to T cell receptors (TCR) recognizing antigenic peptides derived from tumor-associated antigen FMNL1/KW13 or the murine homolog FRL and being capable of inducing peptide specific killing of a target cell. The present invention is further directed to antigenic peptides derived from tumor-associated antigen FMNL1/KW13, to an antigen specific T cell, comprising said TCR, to a nucleic acid coding for said TCR and to the use of the antigen specific T cells for the manufacture of a medicament for the treatment of malignancies characterized by overexpression of FMNL1/KW13. The present invention is further disclosing a method of generating antigen specific allorestrictive T cells.

BACKGROUND OF THE INVENTION

The present invention concerns the field of immunotherapies in B cell neoplasms, in particular B cell lymphoma, including acute and chronic lymphocytic leukemias.

The incidence of B cell neoplasms is increasing, especially in Western Countries (NCI, SEER). Most cases of low grade lymphoma are diagnosed at advanced stages where no curative standard therapy is available. In chronic lymphocytic leukemia (CLL), there is still no established curative therapy available at any time point of diagnosis. In contrast, patients with high grade lymphoma or acute lymphoblastic leukemia benefit from intensive and potentially curative chemotherapy regimens. However, longterm prognosis is unfavourable for adult patients with recurrent disease. Thus, novel therapies are needed.

Immunotherapy has been shown to be highly successful in low grade lymphoma including CLL. There are target specific therapies using monoclonal antibodies which are directed against surface antigens as CD20 (Rituximab) and CD52 (Alemtuzumab) (1,2). However, tumor escape occurs due to down regulation of the target antigen from the cell surface. T cells are able to recognize peptides associated to MHC molecules derived from extra- and intracellular antigens. T cells are currently applied associated to allogeneic stem cell transplantation and responsible for a Graft versus leukemia effect (GvL effect) which has been shown to be present in different B cell neoplasms (3-5). However, one major disadvantage of this approach is Graft versus host disease (GvHD) due to transferred T cells unspecifically recognizing allogeneic MHC molecules. Using allorestricted peptide-specific T cells it might be possible to circumvent central tolerance against tumor associated self peptides and simultaneously dissociate beneficial graft versus leukemia effect from detrimental graft versus host disease (6,7).

Krackhardt et al., “Identification of tumor associated antigens in chronic lymphocytic leukaemia by SEREX”, Blood September 2002, vol. 100, no. 6, pages 2123-2131, describe the identification of KW13/FMNL1. Here, peptide-specific autologous T cells were generated recognizing one single FMNL1-derived peptide (TLLHYLVKV). However, it turned out that these T cells did not recognize tumor cells as described in the paper. Thus, it is likely that the specific peptide is not an epitope presented on the surface of CLL cells. Moreover, the specific peptide has not been listed. In addition, no specific TCR has been described.

The identification of an antigenic epitope, however is of fundamental importance to use a specific antigen as target for a therapeutic approach as tumor cells can be only targeted if the specific peptide is presented on the surface of a cell. Given a protein length of 1100 amino acids, there are 1091 different nona-peptides which can be used for pulsing and most of them may not bind to the restriction element and/or are not produced by the immune proteasome, thus they are mostly not presented on the surface of a tumor cell.

Mayr et al., “Transduction of CLL cells by CD40 ligand enhances an antigen-specific immune recognition by autologous T cells”, Blood November 2005, vol. 106, no. 9, compare the functional reactivity of T cell lines generated by stimulation with CD40L-AAV-transduced CLL cells, GFP-AAV-transduced CLL cells as well as native CLL cells and CLL cells stimulated by CD40-Ligand. Their read-out is an ELISPOT-assay where they use peptide-pulsed APC using different peptides for pulsing. They claim that they have generated antigen-specific T cells. However, several important controls are missing in order to prove the significance of the peptides used for detection of specific antigen recognition, as for example peptides and well characterized T cells for positive and negative controls, peptide dilution and tetramer-staining of T cell lines. As CD40L-activated CLL cells may prime for many antigens and peptide-pulsed CLL cells can express many other antigens, peptide-specificity is not shown in the manuscript. Moreover, no specific peptide is mentioned concerning KW13. The authors merely mention “KW13” in the methods section. KW13 is actually not a peptide but the whole FMNL1 protein. In addition, no specific TCR has been discovered and described. Thus regarding Mayr et al., no precise peptide has been described concerning KW13/FMNL1, no peptide-specificity has been proven, no epitope has been discovered, no specific TCR was shown. This is exactly the critical development which has been undertaken in our last work and which motivates us for the patent claims.

SUMMARY OF THE INVENTION

It one object of the present invention to generate allorestrictive T cells that bear TCR that have the capacity to recognize their MHC-peptide ligands on tumor cells. Furthermore, it is an object of the invention to provide a T cell based pharmaceutical composition that can be used for treating a patient suffering from lymphoma without a risk of graft-versus-host-disease (GVHD).

These objects are achieved by the subject-matter of the independent claims. Preferred embodiments are set forth in the dependent claims.

The inventors have generated allorestricted peptide-specific T cells with specificity against a defined peptide derived from the tumor associated antigen FMNL1/KW13. For example, it could be demonstrated (I) the identification of specific T cell receptor chains which are allo-HLA-A2 restricted and specific for our selected peptide RLPERMTTL (SEQ ID NO: 2) as well as the murine homologue RLPERMNTL (SEQ ID NO: 5) derived from the murine FMNL1 homologous protein and (II) that the selected peptide RLPERMTTL derived from FMNL1/KW13 is a natural presented epitope overexpressed on malignant tissue shown by specific cytotoxicity against lymphoma cell lines, other malignant cell lines and primary tumor material of patients with chronic lymphocytic leukaemia and acute lymphoblastic leukemia. These T cells will be helpful for the development of immunotherapies against malignant lymphoma.

In healthy tissue, FMNL1/KW13 is almost exceptionally expressed in leukocytes. FMNL1/KW13-specific allorestricted T cells, therefore, are also useful in the development of immunotherapeutic strategies against rheumatoid diseases.

Using the present approach, allorestricted peptide-specific T cells with specificity against the selected peptides which also show specific cytotoxicity against malignant cell lines derived from lymphoma, renal cell carcinoma, melanoma, breast cancer, as well as cells from patients with chronic lymphocytic leukaemia, acute lymphoblastic leukaemia cells and also activated lymphocytes could be generated. In contrast, healthy tissue cell lines as fetal fibroblasts and fetal kidney cells were not recognized (FIGS. 4-12).

DETAILED DESCRIPTION OF THE INVENTION

According to a first aspect, the invention provides a T cell receptor (TCR) recognizing antigenic peptides derived from tumor-associated antigen FMNL1/KW13 or murine FRL and capable of inducing peptide specific killing of a target cell.

More precise information regarding tumor-associated antigen FMNL1/KW13 may be found in (8), including accession no., suggested function etc.

The term “TCR” as used in the present invention has the common meaning, which usually is attributed to that term in the pertinent field of technology. Thus, a rearranged T cell receptor (TCR) comprises a complex of two chains (α-chain and β-chain) containing a CDR3-region of rearranged TCR VDJ genes mainly involved in the recognition of antigenic determinants (epitopes) represented in the MHC context. More detailed information can be found in “Immunobiology, the immune system in health and disease”, Charles A. Janeway, et al, 5 ed. 2001 and other standard literature.

An “antigenic peptide” as used herein is defined as comprising at least one antigenic determinant, i.e. an epitope. The latter is a part of a macromolecule that is being recognized by the immune system, in the present case specifically by cytotoxic T cells.

Accordingly, the TCR of the present invention specifically recognizes one of the epitopes of any of SEQ ID NO: 1-5 and/or peptides/proteins containing same. It is noted that the epitope according to SEQ ID NO: 2 turned out to be most preferred in the present invention since it is a natural presented epitope overexpressed on malignant tissue and the TCR recognizing same effectively induced a specific cytotoxicity against lymphoma cell lines. The present invention also provides an homologous peptide to epitope of SEQ ID NO: 2, i.e. the murine homologue derived from FRL.

It is noted that the invention is not restricted to the precise amino acid sequences as defined herein, but also include variants of the sequences, for example deletions, insertions and/or substitutions in the sequence, which cause for so-called “silent” changes.

Preferably, such amino acid substitutions are the result of substitutions which substitute one amino acid with a similar amino acid with similar structural and/or chemical properties, i.e. conservative amino acid substitutions.

Amino acid substitutions can be performed on the basis of similarity in polarity, charges, solubility, hydrophobic, hydrophilic, and/or amphipathic (amphiphil) nature of the involved residues. Examples for hydrophobic amino acids are alanine, leucine, isoleucine, valine, proline, phenylalanine, tryptophan and methionine. Polar, neutral amino acids include glycine, serine, threonine, cysteine, thyrosine, asparagine and glutamine. Positively (basic) charged amino acids include arginine, lysine and histidine. And negatively charged amino acids include aspartic acid and glutamic acid.

The allowed degree of variation can be experimentally determined via methodically applied insertions, deletions or substitutions of amino acids in a peptide and testing the resulting variants for their biological activity as an epitope. In case of variation of the TCR-CDR3 region specificity and function of the modified TCR can be experimentally investigated by TCR expression in transduced cells or by purified TCRs analyzed with surface plasmon resonance (e.g. Biacore).

An example of such a variant is the sequence of the murine homologue of SEQ ID NO: 2. Whereas the human sequence is RLPERMTTL (SEQ ID NO: 2), the murine homologue is RLPERMNTL (SEQ ID NO: 5). This variant showed also a very good recognition by TCR.

According to a further preferred embodiment, the TCR contains one or more of the amino acids of SEQ ID NO: 9-14.

In a second aspect, the present invention provides an antigenic peptide derived from tumor-associated antigen FMNL1/KW13 being selected from one of SEQ ID NO: 1-5.

However, also the epitopes of SEQ ID NO: 6-8 are contemplated herein.

According to a third aspect, the present invention provides an antigen specific T cell, comprising a TCR as defined above.

Said T cell preferably is a T cell with effector cell characteristics, more preferably a cytokine producing T cell, a cytotoxic T cell or regulatory T cell, preferably CD4+ or CD8+ T cells. Most preferably, the T cell is an autologous T cell.

In a fourth aspect, the invention provides a nucleic acid coding for a part of a TCR (CDR3-region) as defined above. Respective sequences are provided as SEQ ID NO: 15-20.

An additional aspect is directed to a vector, which comprises the nucleic acid coding for said TCR. This vector is preferably an expression vector which contains a nucleic acid according to the invention and one or more regulatory nucleic acid sequences. Preferably, this vector is a plasmid or a retroviral vector.

The invention further comprises a PBMC, which has been transformed with the vector as defined above. This can be done according to established methods such as those described in Engels et al., 2005 (9).

In a still further aspect, the present invention provides a pharmaceutical composition, which comprises the T cells or PBMCs as explained above and a pharmaceutically acceptable carrier.

Those active components of the present invention are preferably used in such a pharmaceutical composition in doses mixed with an acceptable carrier or carrier material, that the disease can be treated or at least alleviated. Such a composition can (in addition to the active component and the carrier) include filling material, salts, buffer, stabilizers, solubilizers and other materials, which are known state of the art.

The term “pharmaceutically acceptable” defines a non-toxic material, which does not interfere with effectiveness of the biological activity of the active component. The choice of the carrier is dependent on the application.

The pharmaceutical composition can contain additional components which enhance the activity of the active component or which supplement the treatment. Such additional components and/or factors can be part of the pharmaceutical composition to achieve synergistic effects or to minimize adverse or unwanted effects.

Techniques for the formulation or preparation and application/medication of active components of the present invention are published in “Remington's Pharmaceutical Sciences”, Mack Publishing Co., Easton, Pa., latest edition. An appropriate application is a parenteral application, for example intramuscular, subcutaneous, intramedular injections as well as intrathecal, direct intraventricular, intravenous, intranodal, intraperitoneal or intratumoral injections. The intravenous injection is the preferred treatment of a patient.

According to a preferred embodiment, the pharmaceutical composition is an infusion or an injection or a vaccine.

According to a further aspect, the present invention is directed to the use of the antigen specific T cells or PBMCs as explained above for the manufacture of a medicament for the treatment of malignancies characterized by overexpression of FMNL1/KW13, preferably chronic lymphocytic leukemia (CLL), or rheumatoid diseases.

In a further aspect, the invention provides a method of generating antigen specific allorestrictive T cells comprising the steps of

a) providing a FMNL1/KW13 (or FRL) derived antigenic peptide as defined above; b) pulsing antigen presenting cells (APCs) with said peptide; c) priming peripheral blood lymphocytes (PBLs) with said APCs; d) selecting those T cells which are specific for the resulting MHC-peptide ligand.

The APC's are preferably selected from dendritic cells, activated B cells, monocytes, macrophages, activated T cells, hematological malignancies with antigen presenting capacities and/or EBV-transformed lymphoblastoid cell lines.

Dendritic cells (DC) are in particular preferred. Mature dendritic cells (DCs) express both MHC class I and class II molecules at high levels, along with a wide variety of costimulatory molecules, which provide them with the full capacity to prime naïve T cells that have not encountered antigen previously. They also have all the necessary genes/proteins that allow them to process and present antigens form intracellular proteins in their MHC class I and class II molecules. Thus, they are optimal antigen presenting cells (APCs) to use as stimulating cells for induction of both CD4 and CD8 T cells responses.

The selection step d) is preferably performed by means of measuring the cytokine release of the T cells or other measures of T cell activation. For example, the activated T cells can be cloned as individual cells and following expansion, the T cell clones can be analyzed for their MHC-peptide specificity and those with the desired specificity can be selected for further use (10). Alternatively, soluble MHC-peptide ligands in various forms, such as tetramers, can be marked with a fluorescent label and incubated with the activated T cells. Those T cells bearing TCR that interact with the tetramers can then be detected by flow cytometry and sorted on the basis of their fluorescence (11). Furthermore, T cells can be stimulated for short periods of time with tumor cells to which they should react and their interferon gamma secretion detected by capture reagents, for example as published (12).

According to a preferred embodiment, the method of the invention further comprises the step of expanding the T cells selected in d) ex vivo. This can be done by co-culturing the selected T cells with APC generated in the same manner as used for their initial priming, adding new APC to the T cell cultures every 7-10 days and providing the cells with fresh culture medium on a regular basis that contains supplementary cytokines, dependent upon the type of T cell that one is expanding.

The present invention in the following is illustrated by the Figures and Examples presented below, which in no way should be construed to be limiting the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1: Fold expression of FMNL1/KW13 mRNA in normal tissue compared to skeletal muscle investigated by quantitative RT-PCR.

FIG. 2: Fold expression of FMNL1/KW13 mRNA in PBMC, native CLL samples and acute leukaemia samples compared to skeletal muscle investigated by quantitative RT-PCR.

FIG. 3: Fold expression of FMNL1/KW13 mRNA in malignant cell lines compared to skeletal muscle investigated by quantitative RT-PCR.

FIG. 4: Enrichment of allorestricted KW13-PP2-specific T cells by Tetramer sorting. Bulk cultures before sorting, enriched T cell lines and 4 cloned T cells are stained with anti-human CD8 APC and KW13-PP2-Tetramer-PE.

FIG. 5: Mini-Chromium-Assay to detect KW13-PP2-specific killing of cloned T cells. ⁵¹Cr-labeled targets are T2 cells pulsed with the specific peptide PP2 and unpulsed T2 cells as controls.

FIG. 6: Functional analysis of KW13-PP2 specific T cell lines and clones. Investigation of T cell affinity of 5 different T cell lines and clones in response to T2 cells pulsed with titrated concentrations of the specific peptide KW13-PP2.

FIG. 7: Functional analysis of KW13-PP2 specific T cell lines and clones. Bioplex-Multianalysis ELISA of PP2-SC22 in response to T2 cells pulsed with the specific peptide KW13-PP2, T2 cells pulsed with the Flu-peptide (MP58) and BJ18 lymphoma cells.

FIG. 8: Titration of the Effector:Target-Ratio with (a) PP2-SC13 as effector cells and KW13-PP2-pulsed T2 cells as targets and (b) PP2-SC14 as effector cells and BJ18 lymphoma cells as targets.

FIG. 9: Functional analysis of KW13-PP2 specific T cell lines and clones.

(a) Specific cytotoxicity of PP2-SC14 in response to pulsed T2 cells and different malignant cell lines and primary healthy cell material and (b) specific cytotoxicity of PP2-PC1, PP2-SC14 and PP2-SC19 against KW13-PP2-pulsed T2 cells, unpulsed T2 cells and acute lymphoblastic leukemia (ALL).

FIG. 10: Overview of specific cytotoxicity of cloned KW13-PP2-specific T cells against malignant cell lines and primary tumor material.

FIG. 11: Overview of specific cytotoxicity of cloned KW13-PP2-specific T cells against healthy PBMC subpopulations and cell line derived from healthy tissue.

FIG. 12: Specific cytotoxicity of PP2-SC22 against T2 cells pulsed with the peptide FMNL1-PP2, the murine homologue FRL-PP1, a highly homologous peptide derived from HDAC6 as well as native and CD40-activated CLL cells.

FIG. 13. Generation of the FMNL1-specific antibody. (A) Human FMNL1 sequence (Swiss-Prot database, Accession No. 095466). Matched peptides detected by mass spectrometry analysis are shown (bold and framed) covering 24% of the protein. (B) Four different monoclonal antibody supernatants (5C9, 5B12, 6F2, 5A1) were tested in a Western blot using 50 μg of cell lysates from T293 cells transfected with pCMV-FMNL1 (F) and pCMV-Vector alone (M).

FIG. 14. Peptide competition assay. Peptide candidates derived from FMNL1 were investigated for their potential binding ability to HLA-A2. Therefore, different FMNL1-derived peptides were loaded on T2 cells and afterwards pulsed with the tyrosinase-derived peptide (Tyr). Flu was used as positive control. IPS as well as peptide pulsed T2 cells, which were afterwards not pulsed with tyrosinase, were used as negative controls, Tyrosinase-specific recognition was investigated by the tyrosinase-specific T-cell clone IVSB in a ⁵¹Cr-release assay at effector:target ratio of 2.5:1.

FIG. 15. TCR analysis of the FMNL1-PP2-specific T-cell clone SK22. (A) Analysis of the TCR α-chain repertoire of clone SK22 was performed using 34 single V alpha segment-specific primers. The primers Vα14 (band at 401 bp) and Vα14.1 (band at 459 bp) amplified identical in-frame CDR3-sequences. Control primers were used to amplify the constant chain (547 bp). Additional fuzzy bands did not result in any readable sequence. (B) TCR β-chain analysis was performed using 37 V beta segment-specific primers, The primers Vβ13 (bands at 278 and 632 bp) and Vβ14 (bands at 187 and 541 bp) resulted in identical in-frame CDR3-sequences. The primers for Vβ6.2 and Vβ6.3 (bands at 171 and 439 bp) resulted in amplified sequences with out-off-frame gene rearrangements. Additional fuzzy bands did not result in any readable sequence. Control primers were used to amplify the constant chain (351 bp). (C) The FMNL1-specific T-cell clone was stained with a FITC-conjugated anti-human Vβ14-specific antibody and a PE-conjugated anti-human CD8 antibody (right plot). The isotype control is shown in the left plot.

FIG. 16. Crossreactivity against HLA-A*3303. IFNγ-release was investigated by ELISA to test the FMNL1-PP2-specific T-cell clone against C1R cells transfected with HLA-A*3303 at effector:target ratio of 1:2. C1R cells transfected with HLA-A*0201 were used as positive control and untransfected C1R cells as well as C1R cells transfected with HLA*6601 as negative controls. Error bars indicate the standard deviation of tested duplicates. Results shown are representative for two experiments.

EXAMPLES Antigen Selection

Allorestricted peptide-specific T cells should be directed against tumor associated antigens with specific characteristics. These antigens should have a most possibly restricted expression to the tumor cell to avoid side effects and should play an important role for vitality and growth of the tumor cell to reduce the risk of target down regulation. We previously identified 14 novel tumor associated antigens using the SEREX (serological identification by recombinant expression cloning) approach in CLL (8). These antigens have been extensively tested for their potential use as target antigens and we selected a few of them for our ongoing studies. FMNL1/KW13 (AF432213) is a formin related protein in leukocytes and has been first described using the SEREX approach in CLL (8). We investigated the mRNA expression of FMNL1/KW13 using quantitative RT-PCR. We observed expression of FMNL1 in healthy tissue mostly in PBMC and to a much lesser extent in bone marrow and thymus. However, we have not seen major expression in any healthy tissue (FIG. 1). In contrast, FMNL1/KW13 is highly overexpressed in 60% of CLL samples tested (FIG. 2 a), some acute leukemia samples (FIG. 2 b) and malignant cell lines (FIG. 3). Developing specific effectors against peptides derived from FMNL1/KW13 might be therefore highly useful for the development of immunotherapies against malignant lymphomas and also for the development of antirtheumatic treatment tools based on the almost exceptional expression of FMNL1/KW13 in leukocytes.

Peptides derived from FMNL1 were selected using prediction algorithms for HLA-binding, proteasomal cleavage sites and TAP transportation (13-16). We are also investigating predicted peptide-antigen candidates of the B cell receptor α-chain (Table 1).

TABLE 1 Peptides derived from FMNL1/KW13 (or FRL) and B cell receptor α-chain selected for generation of allorestricted peptide- specific T cells Name Sequence KW13-PP1 VLLEYLAFA (SEQ ID NO: 1) KW13-PP2 RLPERMTTL (SEQ ID NO: 2) KW13-PP6 CVNEIALSL (SEQ ID NO: 3) KW13-PP7 RLRLTESDKL (SEQ ID NO: 4) FRL RLPERMNTL (SEQ ID NO: 5) BCR1 GLQGTYQDV (SEQ ID NO: 6) BCR2 YLGPGCQAL (SEQ ID NO: 7) BCR3 GTYQDVGSL (SEQ ID NO: 8)

Generation of Allorestricted Peptide Specific T Cells

T2 cells which are defective in transporters associated with antigen-processing (TAP) can be efficiently loaded with exogenous HLA-A*0201 binding peptides and were pulsed with selected peptides at different concentrations. Mainly concentrations of 10 μM and 1 μM were used for pulsing. Peripheral blood mononuclear cells (PBMC) from HLA-A2-negative donors were isolated by Ficoll density gradient. T cells were negatively isolated using magnetic bead depletion (Dynal). T cells were then cultured with peptide-pulsed irradiated T2 cells at ratios of 1:10 to 1:100. Cytokines as IL-7 (5 ng/ml), IL-15 (5 ng/ml) and IL-2 (50 U/ml) were added. Restimulations were performed after 5-7 days using again peptide-pulsed T2 cells, Cultured T cells were stained with HLA-tetrameric complexes and anti-CD8 monoclonal antibodies and were sorted using a flow cytometry sorter. Sorted T cells were cloned by limiting dilution as well as cultured in oligoclonal T cell lines. These clones and unstimulated T cell lines were unspecifically restimulated with allogeneic feeder cells (PBMC pools) and OKT3. T cells were analyzed for their specificity using ⁵¹Cr release assays, ELISA and tetramer staining.

Using this approach we were able to generate allorestricted peptide-specific T cells with specificity against the selected peptide KW13-PP2. These T cells also show specific cytotoxicity against malignant cell lines, chronic lymphocytic leukaemia cells, acute lymphoblastic leukaemia cells and also activated lymphocytes (FIG. 4-12).

The inventors are currently investigating the T cell receptor (TCR) repertoire of the generated T cell lines and clones. One example is the oligoclonal T cell line PP2-PC1, presenting two α-chains and three β-chains which are involved in peptide-specific killing of allorestricted T cells (Table 2). Subcloning of this T cell line has been performed to identify the specific TCR chain responsible for peptide-specific killing. Clone SC22 shows a singular α-(Vα14J41) and β-chain (Vβ14J2.5) which is already represented in the T cell line PP2-PC1, demonstrating the fundamental functional role of these two CDR3-regions in allorestricted FMNL1-PP2-specificity (Table 3).

TABLE 2 T cell receptor analysis of PP2-PC1 demonstrating the pattern of an oligoclonal T cell line CDR3 region CDR3 region Alignment for Alignment for cDNA Amino acid Nomenclature V-gene J-gene sequence sequence TCR-α-chains: 1. IMGT TRAV38- TRAJ41*01 GCT TAT GAA A Y E N S 2/DV8*01 AAT TCC GGG G Y A L N TAT GCA CTC F AAC TTG (SEQ ID No: 9) (SEQ ID No: 15) Arden et al. Vα14 J41 GCT TAT GAA A Y E N S AAT TCC GGG G Y A L N TAT GCA CTC F AAC TTC (SEQ ID No: 9) (SEQ ID No: 15) 2. IMGT TRAV21*02 TRAJ21*01 GCT GTG AGG A V R L S CTA AGT ::C # F N K F TTC AAC AAA Y F TTT TAG TTT SEQ ID NO: 10 SEQ ID No: 16 Arden et al. Vα23 J21 GCT GTG AGG A V R L S CTA AGT ::C # F N K F TTC AAC AAA Y F TTT TAC TTT SEQ ID NO: 10 SEQ ID No: 16 TCR-β-chains: 3. IMGT TRBV7-4*01 TRBJ2-3*01 CAG CAG CTT Q Q L I A ATT GCG GGA G G P T D GGG CCT ACA T Q Y P GAT ACG CAG SEQ ID NO: 11 TAT TTT SEQ ID No: 17 Arden et al. Vβ6.1 Jβ2.3 CAG CAG GTT Q Q L I A ATT GCG GGA G G P T D GGG CCT ACA T Q Y F GAT ACG CAG SEQ ID NO: 11 TAT TTT SEQ ID No: 17 4. IMGT TRBV7-4*01 TRBJ2-3*01 GCC AGC AGC A S S L L TTA TTG CGG R E G # T GAG GGC CT: D T Q Y F ACA GAT ACG SEQ ID NO: 12 CAG TAT TTT SEQ ID No: 18 Arden et al. 4β6.1 Jβ2.3 GCC AGC AGC A S S L L TTA TTG GCG T E G # T GAG GGC CT: D T Q Y F ACA GAT ACG SEQ ID NO: 12 CAG TAT TTT SEQ ID No: 18 5. IMGT TRBV27*01 TRBJ2-5*01 GCC AGC AGT A S S F L TTT CTG GGG G E T Q Y GAG ACC CAG F TAG TTC SEQ ID NO: 13 SEQ ID No: 19 Arden et al. vβ14 Jβ2.5 GCC AGC AGT A S S F L TTT CTG GGG G E T Q Y GAG ACC CAG F TAC TTC SEQ ID NO: 13 SEQ ID No: 19 6. IMGT TCRBV11- TRBJ2-7*01 GCC AGC AGC A S S L A 2*01 TTA GCT TTC F G Q G R GGA CAG S Y E Q Y GGG GGC TCC F TAC GAG CAG SEQ ID NO: 14 TAC TTG SEQ ID No: 20 Arden et al. Vβ21 Jβ2.7 GCC AGC AGC A S S L A TTA GCT TTC F G Q G R GGA CAG S Y E Q Y GGG GGC TCC F TAC GAG CAG TAC TTC SEQ ID NO: 14 SEQ ID No: 20

TABLE 3 T cell clone SC22 shows the following pattern for α- and β-chain (Vα14J41; Vβ14J2.5): Variable CDR3 region CDR3 region chain cDNA sequence Amino acid sequence vα14J4l GCT TAT GAA AAT A Y E N S G Y A L N (Arden et al.) TCC GGG TAT GCA F CTC AAC TTC (SEQ ID No: 9) (SEQ ID No: 15) Vβ14J2.5 GCC AGC AGT TTT A S S F L G E T Q Y (Arden et al.) CTG GGG GAG ACC F GAG TAC TTC SEQ ID NO: 13 (SEQ ID NO: 19)

TABLE 4 Prediction scores of selected peptides derived from FMNL1 TAP- Proteasomal HLA-A2 binding transportation* cleavage sites† Peptide SYFPEITHY²⁸ BIMAS²⁹ TAP³⁰ TAP³¹ PAProC II³² FMNL1-PP1 26 1620 1/0 0/1 +++(3) VLLEYLAFA FMNL1-PP2 24 201 4/0 2/1  ++(2) RLPERMTTL FMNL1-PP3 25 15 2/2 1/2 +++(2) ELQEQVALL FMNL1-PP4 27 101 2/2 2/1 +++(2) FINIVVHSV FMNL1-PP5 14 1, 1 1/1 0/0   −(1) QSLDALLEM FMNL1-PP6 20 7, 7 2/1 1/0  ++(1) CVNEIALSL FMNL1-PP7 22 20, 4 2/1 2/1  ++(2) RLRLTESDKL PMNL1-PP8 31 592 2/0 1/1  ++(4) TLLHYLVKV *Number of favorable versus (/) unfavorable amino acids †Probability of cleavage at the C-terminus: +++ very strong. ++ strong, + weak, − improbable, (number of predicted cute within the peptide)

LITERATURE

-   (1) Maloney D. G., A. J. Grillo-Lopez, et al. (1997). IDEC-C2B8     (Rituximab) anti-CD20 monoclonal antibody therapy in patients with     relapsed low-grade non-Hodgkin's lymphoma. Blood 90 (6): 2188-2195. -   (2) Rai K. R., C. E. Freter, et al. (2002). Alemtuzumab in     previously treated chronic lymphocytic leukemia patients who also     had received fludarabine. J Clin Oncol 20 (18): 3891-3897. -   (3) Marks D. I., R. Lush, et al. (2002). The toxicity and efficacy     of donor lymphocyte infusions given after reduced-intensity     conditioning allogeneic stem cell transplantation. Blood 100     (9):3108-14. -   (4) Khouri I. F., M. S. Lee, et al. (2003). Nonablative allogeneic     stem-cell transplantation for advanced/recurrent mantle-cell     lymphoma. J Clin Oncol. 21 (23):4407-12. -   (5) Schetelig J., C. Thiede, et al. (2003). Evidence of a     graft-versus-leukemia effect in chronic lymphocytic leukemia after     reduced-intensity conditioning and allogeneic stem cell     transplantation: the Cooperative German Transplant Study Group. J     Clin Oncol 21 (14): 2747-2753. -   (6) Heath W. R., M. E. Hurd, et al. (1989). Peptide-dependent     recognition of H-2 Kb by alloreactive cytotoxic T lymphocytes.     Nature 341 (6244): 749-752. -   (7) Sadovnikova E., H. J. Stauss (1996). Peptide-specific cytotoxic     T lymphocytes restricted by nonself major histocompatibility complex     class I molecules: reagents for tumor immunotherapy. PNAS 93 (23):     13114-13118. -   (8) Krackhardt A. M.*, M. Witzens*, et al. (2002a). Identification     of tumor associated antigens in chronic lymphocytic leukemia by     SEREX. Blood 100 (6): 2123-2131. [*first coauthorship] -   (9) Engels B., E. Noessner, et al. (2005). Redirecting human T     lymphocytes toward renal cell carcinoma specificity by retroviral     transfer of T cell receptor genes. Hum Gene Ther 16 (7): 799-810. -   (10) Schendel D. J., R. Oberneder, et al. (1997). Cellular and     molecular analyses of major histocompatibility complex (MHC)     restricted and non-MHC-restricted effector cells recognizing renal     cell carcinomas: problems and perspectives for immunotherapy. J Mol     Med 75 (6): 400-413. -   (11) Yee C., P. A. Savage, et al. (1999). Isolation of high avidity     melanoma-reactive CTL from heterogenous populations using     peptide-MHC tetramers. J Immunol 162 (4): 2227-2234. -   (12) Becker C., H. Pohla, et al. (2001). Adoptive tumor therapy with     T lymphocytes enriched through an IFN-gamma capture assay. Nat Med 7     (10): 1159-1162. -   (13) Parker K. C., M. A. Bednarek, et al. (1994). Scheme for ranking     potential HLA-A*0201 binding peptides based on independent binding     of individual peptide side chains. J Immunol 152 (1): 163-175. -   (14) Raammensee H., J. Bachmann, et al. (1999). SYFPEITHI: database     for MHC ligands and peptide motifs; Immunogenetics 50 (3-4):     213-219. -   (15) Kuttler C., A. K. Nussbaum, et al. (2000). An algorithm for the     prediction of proteasomal cleavages. J Mol Biol 298 (3): 417-429. -   (16) Larsen M. V., C. Lundegaard, et al. (2005). An integrative     approach to CTL epitope prediction: A combined algorithm integrating     MHC class I binding, TAP transport efficiency, and proteasomal     cleavage predictions. Eur J Immunol 35 (8): 2295-2303. -   (17) Arden B., S. Clark, et al. (1995). Human T-cell receptor     variable gene segment families. Immunogenetics 42: 455-500. 

1. A T cell receptor (TCR) specifically recognizing antigenic peptides derived from tumor-associated antigen FMNL1/KW13 or murine FRL and capable of inducing peptide specific killing of a target cell.
 2. The TCR of claim 1, wherein the TCR contains one of the amino acids of SEQ ID NO: 9-14.
 3. The TCR of claim 1, which specifically recognizes one of the peptides of SEQ ID NO: 1-5.
 4. Antigenic peptides derived from tumor-associated antigen FMNL1/KW13 or murine FRL selected from SEQ ID NO: 1-5.
 5. The antigenic peptide of claim 4, which is the peptide of SEQ ID NO:
 2. 6. An antigen specific T cell, comprising a TCR as defined in claim
 1. 7. The T cell of claim 6, wherein the T cell is a T cell with effector cell characteristics.
 8. The T cell of claim 7, wherein the T cell with effector cell characteristics is a cytokine producing T cell, a cytotoxic T cell or regulatory T cells.
 9. The T cell of claim 8, which is a CD4+ or CD8+ T cell.
 10. The T cell of claim 9, which is an autologous T cell.
 11. A nucleic acid coding for a TCR defined in claim 1 or comprising or consisting of one of SEQ ID NO: 15-20.
 12. A vector, which comprises the nucleic acid of claim
 11. 13. The vector of claim 12, which is a plasmid or a retroviral vector.
 14. A PBMC, which has been transformed with the vector of claim 12 or
 13. 15. A pharmaceutical composition, which comprises the T cells of claim 6 or the PBMC of claim 14 and a pharmaceutically acceptable carrier.
 16. The pharmaceutical composition of claim 15, which is an infusion, injection or a vaccine.
 17. A method of treating a patient suffering from a malignancy characterized by overexpression of FMNL1/KW13, comprising the administration of the antigen specific T cells of claim 6 or the PBMC of claim 14 or a pharmaceutical composition of claim 15 in a therapeutically effective amount to said patient.
 18. The method of claim 17, wherein the malignancy is selected from chronic lymphocytic leukemia (CLL), or rheumatoid diseases.
 19. A method of generating antigen specific allorestrictive T cells comprising the steps of a) providing a FMNL1/KW13 derived antigenic peptide as defined in claim 3; b) pulsing antigen presenting cells (APCs) with said peptide; c) priming peripheral blood lymphocytes (PBLs) with said APCs; d) selecting those T cells which are specific for the resulting MHC-peptide ligand.
 20. The method of claim 19, wherein the APCs are selected from dendritic cells, activated B cells, monocytes, macrophages, activated T cells, hematological malignancies with antigen presenting capacities and/or EBV-transformed lymphoblastoid cell lines. 